Your search keyword '"Totoni, Ehsan"' showing total 27 results

1. HiFrames: High Performance Data Frames in a Scripting Language

Author

Totoni, Ehsan, Hassan, Wajih Ul, Anderson, Todd A., and Shpeisman, Tatiana

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

Data frames in scripting languages are essential abstractions for processing structured data. However, existing data frame solutions are either not distributed (e.g., Pandas in Python) and therefore have limited scalability, or they are not tightly integrated with array computations (e.g., Spark SQL). This paper proposes a novel compiler-based approach where we integrate data frames into the High Performance Analytics Toolkit (HPAT) to build HiFrames. It provides expressive and flexible data frame APIs which are tightly integrated with array operations. HiFrames then automatically parallelizes and compiles relational operations along with other array computations in end-to-end data analytics programs, and generates efficient MPI/C++ code. We demonstrate that HiFrames is significantly faster than alternatives such as Spark SQL on clusters, without forcing the programmer to switch to embedded SQL for part of the program. HiFrames is 3.6x to 70x faster than Spark SQL for basic relational operations, and can be up to 20,000x faster for advanced analytics operations, such as weighted moving averages (WMA), that the map-reduce paradigm cannot handle effectively. HiFrames is also 5x faster than Spark SQL for TPCx-BB Q26 on 64 nodes of Cori supercomputer.

Published

2017

2. HPAT: High Performance Analytics with Scripting Ease-of-Use

Author

Totoni, Ehsan, Anderson, Todd A., and Shpeisman, Tatiana

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

Big data analytics requires high programmer productivity and high performance simultaneously on large-scale clusters. However, current big data analytics frameworks (e.g. Apache Spark) have prohibitive runtime overheads since they are library-based. We introduce a novel auto-parallelizing compiler approach that exploits the characteristics of the data analytics domain such as the map/reduce parallel pattern and is robust, unlike previous auto-parallelization methods. Using this approach, we build High Performance Analytics Toolkit (HPAT), which parallelizes high-level scripting (Julia) programs automatically, generates efficient MPI/C++ code, and provides resiliency. Furthermore, it provides automatic optimizations for scripting programs, such as fusion of array operations. Thus, HPAT is 369x to 2033x faster than Spark on the Cori supercomputer and 20x to 256x times on Amazon AWS.

Published

2016

3. Structure-adaptive parallel solution of sparse triangular linear systems

Author

Totoni, Ehsan, Heath, Michael T., and Kale, Laxmikant V.

Published

2014

4. Parallelizing Julia with a Non-Invasive DSL (Artifact)

Author

http://dx.doi.org/10.4230/LIPIcs.ECOOP.2017.4, Anderson, Todd A., Liu, Hai, Kuper, Lindsey, Totoni, Ehsan, Vitek, Jan, Shpeisman, Tatiana, http://dx.doi.org/10.4230/LIPIcs.ECOOP.2017.4, Anderson, Todd A., Liu, Hai, Kuper, Lindsey, Totoni, Ehsan, Vitek, Jan, and Shpeisman, Tatiana

Abstract

This artifact is based on ParallelAccelerator, an embedded domain-specific language (DSL) and compiler for speeding up compute-intensive Julia programs. In particular, Julia code that makes heavy use of aggregate array operations is a good candidate for speeding up with ParallelAccelerator. ParallelAccelerator is a non-invasive DSL that makes as few changes to the host programming model as possible.

Published

2017

5. Parallelizing Julia with a Non-Invasive DSL

Author

Anderson, Todd A., Liu, Hai, Kuper, Lindsey, Totoni, Ehsan, Vitek, Jan, Shpeisman, Tatiana, Anderson, Todd A., Liu, Hai, Kuper, Lindsey, Totoni, Ehsan, Vitek, Jan, and Shpeisman, Tatiana

Abstract

Computational scientists often prototype software using productivity languages that offer high-level programming abstractions. When higher performance is needed, they are obliged to rewrite their code in a lower-level efficiency language. Different solutions have been proposed to address this trade-off between productivity and efficiency. One promising approach is to create embedded domain-specific languages that sacrifice generality for productivity and performance, but practical experience with DSLs points to some road blocks preventing widespread adoption. This paper proposes a non-invasive domain-specific language that makes as few visible changes to the host programming model as possible. We present ParallelAccelerator, a library and compiler for high-level, high-performance scientific computing in Julia. ParallelAccelerator's programming model is aligned with existing Julia programming idioms. Our compiler exposes the implicit parallelism in high-level array-style programs and compiles them to fast, parallel native code. Programs can also run in "library-only" mode, letting users benefit from the full Julia environment and libraries. Our results show encouraging performance improvements with very few changes to source code required. In particular, few to no additional type annotations are necessary.

Published

2017

6. Parallelizing Julia with a Non-Invasive DSL

Author

Todd A. Anderson and Hai Liu and Lindsey Kuper and Ehsan Totoni and Jan Vitek and Tatiana Shpeisman, Anderson, Todd A., Liu, Hai, Kuper, Lindsey, Totoni, Ehsan, Vitek, Jan, Shpeisman, Tatiana, Todd A. Anderson and Hai Liu and Lindsey Kuper and Ehsan Totoni and Jan Vitek and Tatiana Shpeisman, Anderson, Todd A., Liu, Hai, Kuper, Lindsey, Totoni, Ehsan, Vitek, Jan, and Shpeisman, Tatiana

Abstract

Computational scientists often prototype software using productivity languages that offer high-level programming abstractions. When higher performance is needed, they are obliged to rewrite their code in a lower-level efficiency language. Different solutions have been proposed to address this trade-off between productivity and efficiency. One promising approach is to create embedded domain-specific languages that sacrifice generality for productivity and performance, but practical experience with DSLs points to some road blocks preventing widespread adoption. This paper proposes a non-invasive domain-specific language that makes as few visible changes to the host programming model as possible. We present ParallelAccelerator, a library and compiler for high-level, high-performance scientific computing in Julia. ParallelAccelerator's programming model is aligned with existing Julia programming idioms. Our compiler exposes the implicit parallelism in high-level array-style programs and compiles them to fast, parallel native code. Programs can also run in "library-only" mode, letting users benefit from the full Julia environment and libraries. Our results show encouraging performance improvements with very few changes to source code required. In particular, few to no additional type annotations are necessary.

Published

2017

7. Parallelizing Julia with a Non-Invasive DSL (Artifact)

Author

Todd A. Anderson and Hai Liu and Lindsey Kuper and Ehsan Totoni and Jan Vitek and Tatiana Shpeisman, Anderson, Todd A., Liu, Hai, Kuper, Lindsey, Totoni, Ehsan, Vitek, Jan, Shpeisman, Tatiana, Todd A. Anderson and Hai Liu and Lindsey Kuper and Ehsan Totoni and Jan Vitek and Tatiana Shpeisman, Anderson, Todd A., Liu, Hai, Kuper, Lindsey, Totoni, Ehsan, Vitek, Jan, and Shpeisman, Tatiana

Abstract

This artifact is based on ParallelAccelerator, an embedded domain-specific language (DSL) and compiler for speeding up compute-intensive Julia programs. In particular, Julia code that makes heavy use of aggregate array operations is a good candidate for speeding up with ParallelAccelerator. ParallelAccelerator is a non-invasive DSL that makes as few changes to the host programming model as possible.

Published

2017

8. Power, Reliability, Performance: One System to Rule Them All

Author

Acun, Bilge, Langer, Akhil, Meneses-Rojas, Esteban, Menon, Harshitha, Sarood, Osman, Totoni, Ehsan, and Kalé, Laxmikant

Subjects

Componentes de Hardware, Programación, Algoritmos, Calor, POTENCIA, Condiciones térmicas, PRODUCTIVIDAD, Sistemas inteligentes, COMPUTACIÓN AVANZADA

Abstract

En un diseño basado en el marco de programación paralelo Charm ++, un sistema de tiempo de ejecución adaptativo interactúa dinámicamente con el administrador de recursos de un centro de datos para controlar la energía mediante la programación inteligente de trabajos, la reasignación de recursos y la reconfiguración de hardware. Gestiona simultáneamente la fiabilidad al enfriar el sistema al nivel óptimo de la aplicación en ejecución y mantiene el rendimiento a través del equilibrio de carga

Published

2016

9. HPAT

Author

Totoni, Ehsan, primary, Anderson, Todd A., additional, and Shpeisman, Tatiana, additional

Published

2017

10. A Case Against Tiny Tasks in Iterative Analytics

Author

Totoni, Ehsan, primary, Dulloor, Subramanya R., additional, and Roy, Amitabha, additional

Published

2017

11. Accelerating Scientific Python with Intel Optimizations

Author

Pavlyk, Oleksandr, primary, Nagorny, Denis, additional, Guzman-Ballen, Andres, additional, Malakhov, Anton, additional, Liu, Hai, additional, Totoni, Ehsan, additional, Anderson, Todd, additional, and Maidanov, Sergey, additional

Published

2017

12. Energy-optimal configuration selection for manycore chips with variation

Author

Langer, Akhil, primary, Totoni, Ehsan, additional, Palekar, Udatta, additional, and Kalé, Laxmikant V, additional

Published

2016

13. Power, Reliability, and Performance: One System to Rule them All

Author

Acun, Bilge, primary, Langer, Akhil, additional, Meneses, Esteban, additional, Menon, Harshitha, additional, Sarood, Osman, additional, Totoni, Ehsan, additional, and Kale, Laxmikant V., additional

Published

2016

14. Latte: a language, compiler, and runtime for elegant and efficient deep neural networks

Author

Truong, Leonard, primary, Barik, Rajkishore, additional, Totoni, Ehsan, additional, Liu, Hai, additional, Markley, Chick, additional, Fox, Armando, additional, and Shpeisman, Tatiana, additional

Published

2016

15. Power Management of Extreme-Scale Networks with On/Off Links in Runtime Systems

Author

Totoni, Ehsan, primary, Jain, Nikhil, additional, and Kale, Laxmikant V., additional

Published

2015

16. Energy-efficient computing for HPC workloads on heterogeneous manycore chips

Author

Langer, Akhil, primary, Totoni, Ehsan, additional, Palekar, Udatta S., additional, and Kalé, Laxmikant V., additional

Published

2015

17. Energy-optimal configuration selection for manycore chips with variation.

Author

Langer, Akhil, Totoni, Ehsan, Palekar, Udatta, and Kalé, Laxmikant V.

Subjects

*LINEAR programming, *ENERGY consumption, *HEURISTIC algorithms, *LINEAR substitutions, *MATHEMATICAL optimization

Abstract

Operating chips at high energy efficiency is one of the major challenges for modern large-scale supercomputers. Low-voltage operation of transistors increases the energy efficiency but leads to frequency and power variation across cores on the same chip. Finding energy-optimal configurations for such chips is a hard problem. In this work, we study how integer linear programming techniques can be used to obtain energy-efficient configurations of chips that have heterogeneous cores. Our proposed methodologies give optimal configurations as compared with competent but sub-optimal heuristics while having negligible timing overhead. The proposed ParSearch method gives up to 13.2% and 7% savings in energy while causing only 2% increase in execution time of two HPC applications: miniMD and Jacobi, respectively. Our results show that integer linear programming can be a very powerful online method to obtain energy-optimal configurations. [ABSTRACT FROM AUTHOR]

Published

2017

18. Parallel Programming with Migratable Objects: Charm++ in Practice

Author

Acun, Bilge, primary, Gupta, Abhishek, additional, Jain, Nikhil, additional, Langer, Akhil, additional, Menon, Harshitha, additional, Mikida, Eric, additional, Ni, Xiang, additional, Robson, Michael, additional, Sun, Yanhua, additional, Totoni, Ehsan, additional, Wesolowski, Lukasz, additional, and Kale, Laxmikant, additional

Published

2014

19. Using an Adaptive HPC Runtime System to Reconfigure the Cache Hierarchy

Author

Totoni, Ehsan, primary, Torrellas, Josep, additional, and Kale, Laxmikant V., additional

Published

2014

20. Evaluation of a Feature Tracking Vision Application on a Heterogeneous Chip

Author

Gran, Ruben, primary, Shi, August, additional, Totoni, Ehsan, additional, and Garzaran, Maria J., additional

Published

2014

21. Easy, fast, and energy-efficient object detection on heterogeneous on-chip architectures

Author

Totoni, Ehsan, primary, Dikmen, Mert, additional, and Garzarán, María Jesús, additional

Published

2013

22. Toward Runtime Power Management of Exascale Networks by on/off Control of Links

Author

Totoni, Ehsan, primary, Jain, Nikhil, additional, and Kale, Laxmikant V., additional

Published

2013

23. “Cool” Load Balancing for High Performance Computing Data Centers

Author

Sarood, Osman, primary, Miller, Phil, additional, Totoni, Ehsan, additional, and Kal, Laxmikant V., additional

Published

2012

24. Comparing the power and performance of Intel's SCC to state-of-the-art CPUs and GPUs

Author

Totoni, Ehsan, primary, Behzad, Babak, additional, Ghike, Swapnil, additional, and Torrellas, Josep, additional

Published

2012

25. Simulation-Based Performance Analysis and Tuning for a Two-Level Directly Connected System

Author

Totoni, Ehsan, primary, Bhatele, Abhinav, additional, Bohm, Eric J., additional, Jain, Nikhil, additional, Mendes, Celso L., additional, Mokos, Ryan M., additional, Zheng, Gengbin, additional, and Kale, Laxmikant V., additional

Published

2011

26. ACM SRC poster

Author

Totoni, Ehsan, primary and Kale, Laxmikant V., additional

Published

2011

27. High-throughput stream categorization and intrusion detection on GPU

Author

Khabbazian, Mohammad Hassan, primary, Eslami, Hassan, additional, Totoni, Ehsan, additional, and Khadem, AhmadReza, additional

Published

2010